Abstract: A method and circuit for comparing the frequencies of two clocks (clock—1 and clock—2), without taking into account their phase, is disclosed. Each clock is associated to a circular counter (100-1 and 100-2) which are initialized to different values, and the contents of the circular counters are compared. When the frequencies of the two clocks (clock—1 and clock—2) are equal, both counters (100-1 and 100-2) are incremented at a common frequency and thus, due to the initialization conditions, the contents of both counters can never be equal. Conversely, when the frequencies of the two clocks are different, the counters (100-1 and 100-2) are not increased at a common frequency and thus, after several clock pulses, the contents of the counters are equal, indicating different clock frequencies. In a preferred embodiment, the circular counters (100-1 and 100-2) are 2-bit circular counters.

Abstract: A method and circuit for comparing the frequencies of two clocks (clock—1and clock—2), without taking into account their phase, is disclosed. Each clock is associated to a circular counter (100-1 and 100-2) which are initialized to different values, and the contents of the circular counters are compared. When the frequencies of the two clocks (clock—1 and clock—2) are equal, both counters (100-1 and 100-2) are incremented at a common frequency and thus, due to the initialization conditions, the contents of both counters can never be equal. Conversely, when the frequencies of the two clocks are different, the counters (100-1 and 100-2) are not increased at a common frequency and thus, after several clock pulses, the contents of the counters are equal, indicating different clock frequencies. In a preferred embodiment, the circular counters (100-1 and 100-2) are 2-bit circular counters.

Abstract: Disclosed is a delay interpolator (DI) circuit (or mixer) that can be driven by digital signals. This DI circuit may be incorporated in the loop of a delay interpolator voltage controlled oscillator (DIVCO) circuit. In turn, the digital DIVCO circuit may be inserted in the loop of a phase-locked loop (PLL) circuit for total digitalization thereof. The novel digital delay interpolator circuit (23) has the base structure of the conventional analog delay interpolator circuit except in that, at the first (bottom) level, the two standard NFET input devices which are normally controlled by an analog signal (typically generated by a preceding DAC) are respectively replaced by two arrays (24A, 24B) of smaller NFET devices connected in parallel. The gate of each NFET device of the first array is driven by a bit (c0, c1, . . . ) of the true phase of the digital signal. The gate of each NFET device of the second array is driven by a bit (c0, c1, . . . ) of the complementary phase of the digital signal.

Abstract: A semiconductor structure for making four device SRAMs with stacked polysilicon load resistors (4D/2R SRAM cells) in CMOS FET technology. The structure is formed from a semiconductor substrate with active regions of devices therein and polysilicon lines formed thereupon. A first thick passivating layer is formed of an etch stop layer and a layer of phosphosilicate glass (PSG) above the substrate. A set of first metal contact studs through the first thick passivating layer contacts at least one of the active regions and/or the polysilicon lines. The etch stop layer (26) may be of intrinsic polysilicon or Al.sub.2 O.sub.3. The top surface of the first contact studs is coplanar with the top surface of the first thick passivating layers. A plurality of polysilicon lands formed on the planar structure contact the first contact studs. The polysilicon lands are highly resistive, highly conductive or a mix thereof.

Abstract: A method of forming thin film pseudo-planar polysilicon gate PFETs (pPFETs) simultaneously with bulk PFET and NFET devices in a CMOS or BiCMOS semiconductor structure, comprising the steps of: providing a P-type silicon substrate having a surface that includes a plurality of isolation regions; delineating polysilicon lands at selected isolation regions; forming N-well regions into the substrate at a location where bulk PFETs are to be subsequently formed; forming insulator encapsulated conductive polysilicon studs to provide gate electrodes at desired locations of the structure; forming self-aligned source/drain regions of the bulk NFETs into the substrate; forming self-aligned source/drain regions of the bulk PFETs and pPFETs into the substrate and into the polysilicon lands, respectively; and forming contact regions to the selected locations that include the source/drain regions.

Abstract: A low power TTL/CMOS receiver circuit consists of four stages, each of which is, respectively, comprised of at least two complementary FET devices connected to each other in series. The various stages control each other by a variety of feedback interconnections. The use of feedback loops permits to significantly decrease the DC current in the input stage of the receiver circuit. It also realizes a substantial decrease in AC current consumption, although less significantly. Finally, delay variations between input and output signals are obtained as well as substantial improvements in the symmetry between the true and complement output signals of the receiver circuit.

Abstract: A semiconductor structure including: a semiconductor substrate (18/19) having active regions (21) of devices (T1, . . . ) therein and/or polysilicon lines (23-1, . . .) formedthereupon; a first thick passivating layer (26/27) formed above the substrate having a set of first metal contact studs (30-1, . . .) therein contacting at least one of the active regions (21) and/or the polysilicon lines (23-1, . . . ); the surface of the first contact studs is coplanar with the surface of the first passivating layer; a plurality of polysilicon lands (31-1, . . .) formed on the planar structure in contact with the first contact studs; the polysilicon lands are either highly resistive, highly conductive or a mix thereof; a second thick passivating layer (34/35) formed above the resulting structure having a set of second metal contact-studs (37-1 . . .

Abstract: A manufacturing method is provided for producing a stacked semiconductor structure including: depositing a first thick passivating layer onto the base structure; forming first stud openings in the first thick passivating layer exposing at least one active region and/or one of the polysilicon lines; depositing a first layer of a conductive material to fill the first stud openings and define first contact studs, the upper part of some of the first contact studs comprising the gate electrodes of PFET devices; planarizing the structure to make the top surface of the first contact studs coplanar with the surface of the first thick passivating layer; depositing a thick insulating layer to form the gate dielectric of PFET devices and patterning it to define contact openings to expose selected first contact studs at desired locations; depositing a layer of polysilicon; patterning the polysilicon layer to define polysilicon lands containing the first contact studs at the desired locations; selectively implanting to de

Abstract: A stacked semiconductor structure including a base structure (18/19) is comprised of a semiconductor substrate having active regions (21) of devices (N1, . . . ) formed therein and/or a plurality of polysilicon lines (23-1, . . . ) formed thereupon; a first thick passivating layer (26/27) having a set of first metal contact studs (30-1, . . . ) therein contacting at least one of said active regions (21) and/or said polysilicon lines (23-1, . . . ), the surface of said first metal contact studs being coplanar with the surface of said first thick passivating layer; a plurality of first polysilicon lands (31-1, . . .